How to prove existence of a supremum or infimum – Serlo
General procedure
[Bearbeiten]How do we find the supremum/infimum of a set? there are some strategies:
- Visualize the set: What does the set look like? Try to draw it. You may use a paper, a computer or your imagination!
- Make a hypotheses: Is the set bounded from above? if yes, what is a suitable candidate for a supremum? And why? If not, why is it unbounded? And what about the supremum?
- Find a proof for the supremum/ infimum: Now, how can you show that the suspected supremum/ infimum is indeed one? Or that there is no supremum or infimum due to unboundedness? Take a piece of paper and try to construct a proof. Perhaps, within the proof you may notice that your first step was wrong for some reason. This is a good sign: detecting your own wrong thoughts takes you closer to the actual truth.
- Write down the proof: If you have a plan how to make a proof, formulate it in a short and understandable way - such that anyone who reads it and doesn't know the solution gets the answer as quickly and nicely as possible.
General structure of proof
[Bearbeiten]Proofs that a set has a supremum/ infimum generally follow some patterns, which we want to list here:
Supremum: structure of proof
[Bearbeiten]In order to show that a number is the supremum of a set , you may proceed as follows:
- Prove that is an upper bound of : This is done showing for all .
- Prove that no number is an upper bound of : Take any and show that there is a with .
Infimum: structure of proof
[Bearbeiten]A proof that is the infimum of a set , could look as follows:
- Prove that is a lower bound of : This is done showing for all .
- Prove that no number is a lower bound of : Take any and show that there is a with .
Maximum: structure of proof
[Bearbeiten]the proof makes use of the definition of the maximum:
- Prove that is an upper bound of : This is done showing for all .
- Prove that .
Minimum: structure of proof
[Bearbeiten]In order to show that is the minimum of , you may proceed as for the maximum:
- Prove that is a lower bound of : This is done showing for all .
- Prove that .
Examples for determining supremum/infimum
[Bearbeiten]Finite sets
[Bearbeiten]With finite sets of real numbers, determining the infimum and supremum is simple. These sets must always have a maximum (greatest number) and a minimum (smallest number). The maximum of the set is automatically supremum and the minimum is automatically infimum of the set.
Example (supremum and infimum of a finite set)
Consider the set . Its maximum is and its minimum . The element is included within the set and no element is greater than . So is the maximum. Analogously, the minimum is .
As is a maximum, it is also a supremum of . And analogously, is an infimum.
Exercise (for understanding): Determine the supremum and the infimum of the following sets:
Solution:
- The supremum of is its biggest element . The infimum is the smallest element .
- There is . So the supremum is and the infimum is .
- There is . So supremum and infimum of are both given by .
Intervals
[Bearbeiten]The determination of the infimum and supremum for intervals is quite simple, because the lower boundary point is always the infimum and the upper boundary point is always the supremum:
Theorem (supremum and infimum of intervals)
Let be an interval.So there are with , such that takes one of the following 4 forms:
In that case, is the infimum and the supremum of the interval.
How to get to the proof? (supremum and infimum of intervals)
The above intervals differ in whether the endpoints , are included or not. In any case, we know that for each the following holds: . So we know that is a lower bound and is an upper bound. That means, , . We still have to show that is indeed the greatest lower bound and the smallest upper bound.
Let us assume that there is a , so that is also a lower bound. We can show that this leads to a contradiction:
To show that cannot be a lower bound, we need to find an , so that . To construct such a , we take the mean value between and , which by definition is greater than . It could happen that is so large that the mean value becomes larger than . In this case, is even larger than , so any point of the interval is below and is not a lower bound. In any other case, the mean calue between and is an element of the interval and it is smaller than . So is not a lower bound in this case either. This is the contradiction, we have been looking for: we just showed that in any case, cannot be a lower bound. So is the greatest lower bound, i.e. the infimum. Showing that is a supremum works by analogous arguments.
Proof (supremum and infimum of intervals)
Let be an interval. It does not matter here, whether the boundary points are included or not. For each interval , so is a lower bound. We show that there is no greater lower bound than by contradiction:
Assume that also was a lower bound of . The there is no , such that . We distinguish two cases:
Fall 1: (small interval)
Let . We can estimate
So and hence . By we get
This contradicts the assumption of being a lower bound of .
Fall 2: (large interval)
Now, take . By our assumptions,
So and we have .
But since we have . Again, this contradicts being a lower bound of .
Add a figure depicting both cases.
In both cases, we get a contradiction to being a further lower bound of . So is indeed the infimum of .
The proof that is the supremum is done analogously. We assume that was an upper bound of , which is lower than . If we consider the number for and for , we will get a violation of this bound.
Alternatively, one may use the properties of suprema and Infiuma and apply the following trick: We use . is an infimum of by the above arguments, so is a supremum of .
Exercise (for understanding): Determine the supremum and the infimum of the following sets:
- The supremum is and the infimum is .
- Since , we have that . This is an interval with infimum 1 and supremum 4.
- is the set of all with distance to being less than . That is an open interval . Its infimum is and the supremum is .
- is the set of all real numbers being covered by the sine function. The sine oscillates between and . So we just have an interval . Hence, the infimum of is and the supremum is .
Intervals of integers
[Bearbeiten]Exercise (for understanding): Now, let us consider integer boundaries with . And we only pick out the integer numbers of the intervals:
It helps a lot to know that the sets are all finite:
(Be careful with open boundaries! They remove one entire integer element.) In the first 3 cases, there is and the set is non-empty.
- and
- and
- and
So there is always a supremum or an infimum. However, in the last case can be empty. This happens exactly if . In that case, there is neither a supremum nor an infimum. We only have the improper supremum and the improper infimum . However, those are no real numberes, i.e. no proper suprema/ infima. For , the set is non-empty and we have supremum and infimum .
Sequences
[Bearbeiten]Suprema and infima of sequence elements are often required in mathematics. As those elements form a set, the supremum and infimum is well-defined. The set will have often infinitely, but always countably many elements. Let's start with an example:
Exercise (Sets of sequence elements)
What are the supremum and the infimum of the set . Are they also a maximum or a minimum? Prove all your assumptions!
How to get to the proof? (Sets of sequence elements)
We follow a step-by-step approach:
Proof step: Visualize the set .
The first elements of are:
- ?
So the set is of the form , with all further elements approaching .
Proof step: Give a hypothesis what may be the infimum or the supremum.
We see that the set is bounded from above by . At the same time is an element of the set, so must be the maximum of the set. Furthermore, the set isbounded from below by . Since the elements of the set are getting closer and closer to , there can be no lower bound greater than . It follows that is probably the infimum of the set. Note that we are only making assumptions here because we are arguing intuitively. We still need a solid proof.
Proof step: Find a proof for the supremum / maximum.
We have already established that is probably the maximum amount. So we have to show two things:
- for all
The number is definitely an elements of , namely for there is . In order to prove that is an upper bound of , we need to show . This can be achieved by equivalent transformations:
Now is an obvious statement for natural numbers. But in the proof we must go the opposite way: Since we want to show the inequality , we have to start at and gradually transform this inequality into . This is feasible because we have only used equivalent transformations above.
In the last chapter we have seen that every maximum of a set is automatically the supremum of the set (only the other way round it is not always the case). From this it follows that is the supremum of .
Proof step: Find a proof of the infimum / minimum.
To prove that is an infimum, we have to show
- for all
- For all there is an with
Um auch zu zeigen, dass kein Minimum ist, haben wir außerdem zu beweisen, dass . Zunächst muss ein Beweis for for all gefunden werden:
In order to show that in addition, is not a minimum, we also have to prove that . First of all, we have to find a proof to for all :
Now is an obviously true statement, since is positive. So in the later proof we can get to the inequality starting from by performing the above equivalent transformation backwards (i.e. adding on both sides).
Let now continue with an arbitrary (possibly better bound) . To rule out that this is a better bound, we have to find an with and such that . We choose here the variable and not , because we want to find a concrete element of the set (in mathematics often is used, if we are looking for a concrete ). Let us reformulate this inequality to to find a matching :
Because of , we have and . The Archimedian axiom now guarantees us that we can find a suitable , because according to the Archimedian axiom the fraction becomes smaller than any positive real number.
Finally, we need to show that . Or put in different words, is valid for all . But because there is and therefore . So this is rather simple. Now, we are ready to write down the proof:
Proof (Sets of sequence elements)
We prove that is a maximum (and therefore supremum) of the set and is an infimum but not a minimum of the set .
Proof step: is a maximum of
Proof step: is an element of
For there is . So .
Proof step: is an upper bound of
For all there is
So is greater or equal to any element of .
Proof step: is the infimum of
Proof step: is a lower bound of
For all there is
So is smaller or equal than any element of .
Proof step: No other number greater than can be a lower bound of
Let be arbitrary. Then, and by the Archimedean axiom, there is an with . There is
Since there is an element of which is smaller than . So is no lower bound of .
Proof step: is not a minimum of
There is and hence . So is not an element of and hence not a minimum.
Sets of function values
[Bearbeiten]Exercise
Determine the supremum and the infimum of the set
How to get to the proof?
Let in the following be . We proceed as follows:
Step 1: Visualize the set .
The function drawn in a diagram looks as follows:
The set now consists of all values being hit by the function , which is just the image of .
Step 2: Make a hypothesis which numbers are the supremum and the infimum of the set.
We can assume that is the supremum of . Because , is also hit by the function . So this number is in and should therefore be the maximum of this set.
Furthermore, the assumption that is the infimum of is obvious. The function always seems to be positive, i.e. greater or equal zero. The greater the absolute value of , the closer the function values are to zero (at least that's how it looks at first glance). So should be the infimum of , whereas it is not directly in and therefore it should not be a minimum.
Step 3: Find a proof for the supremum/ maximum.
We assert that is the maximum of the set . Because we can directly see that . Now all that is missing is the proof that is an upper bound of the set . For this we must prove that for all real numbers we have the following inequality:
Let us transform this inequality by means of equivalent transformations:
We already know that the last inequality is fulfilled for all . Since we have only used equivalent transformations, we can later recover the inequality .
Step 4: Find a proof of the infimum / minimum.
Here we must first show that all elements of are greater than or equal to zero. However, is the quotient of two positive numbers, which must be positive again. All elements from are therefore positive and hence greater than or equal to .
Now, we need to show that is also the largest lower bound of . For this, let be arbitrary. We have to find an element from which is smaller than . So there must be a with
Let us transform this inequality by means of equivalent transformations:
In order to take the square root, is required, i.e. . But for the further proof it is no problem to assume , because for the last inequality is always fulfilled. The square number is then always greater than the negative number .
So consider . Then:
For we need to choose an with . This automatically fulfils
hence cannot by a lower bound of .
Proof
We prove that is a maximum and hence a supremum of . Further, we prove that is an infimum but not a minimum of .
Proof step: is the maximum of
Proof step: is an element of
For there is . So .
Proof step: is an upper bound of
There is
So is an upper bound of .
Proof step: is an infimum of
Proof step: is a lower bound of
There is for all :
So 0 is a lower bound of .
Proof step: No number greater than is a lower bound of
Let be arbitrary. For there is
for any real , since is negative then. For choose such that . Then the following inequality is satisfied.
For any there is at least one real number with . For real numbers of this kind we have
So cannot be a lower bound of , which proves that is the largest lower bound of .